Mobile electronic device

ABSTRACT

A mobile electronic device and method are presented. An input operation by a user is received, functions are stored, a remaining battery capacity is measured, and a first image is displayed indicating the remaining battery capacity and full capacity. Battery blocks are set by dividing the full capacity, if an input is entered when the first image is displayed to provide a battery blocks set up. A capacity ratio is calculated based on capacity of each of the battery blocks and the full capacity, and a remaining battery block capacity of the battery blocks is calculated based on the capacity ratio. A function is allocated to the battery blocks, and second images are displayed indicating the capacity ratio and the remaining battery block capacity. The function allocated to the battery blocks for the battery block images is displayed, when the battery blocks are set.

CROSS-REFERENCE TO RELATED APPLICATION

The present application claims priority under 35 U.S.C. §119 to JapanesePatent Application No. 2011-160448, filed on Jul. 22, 2011, entitled“MOBILE DEVICE, PROGRAM and METHOD FOR CONTROLLING A BATTERY”. Thecontent of which is incorporated by reference herein in its entirety.

FIELD

Embodiments of the present disclosure relate generally to mobileelectronic devices, and more particularly relate to mobile electronicdevices comprising a battery.

BACKGROUND

Mobile communication devices can operate with batteries. The mobilecommunication devices include circuits for respective functions thereof.The mobile communication devices are capable of allocating a batterycapacity to each of the functions. However, a user may not know how longeach of the functions to which the battery capacity is allocated may beused.

SUMMARY

A mobile electronic device and method for operating a mobile electronicdevice are presented. An input operation by a user is received, aplurality of functions is stored, a remaining battery capacity of abattery is measured, and a first image is displayed indicating theremaining battery capacity and full capacity of the battery. A pluralityof battery blocks are set by dividing the full capacity of the batteryinto at least two, if a first input operation is entered when the firstimage is displayed to provide a battery blocks set up. A capacity ratiois calculated based on capacity of each of the battery blocks and thefull capacity, and a remaining battery block capacity of each of thebattery blocks is calculated based on the capacity ratio. At least onefunction is allocated to at least one of the battery blocks, and aplurality of second images are displayed indicating the capacity ratioand the remaining battery block capacity. The function allocated to oneof the battery blocks for one of the second images is displayed, whenthe battery blocks are set.

In an embodiment, a mobile electronic device comprises a battery, aninput module, a memory module, a measuring module, a display module, asetting module, a calculation module, a function allocation module, anda processor. The input module receives an input operation by a user, thememory module stores functions, and the measuring module measures aremaining battery capacity of the battery. The display module displays afirst image indicating the remaining battery capacity and full capacityof the battery. The setting module sets a plurality of battery blocks bydividing the full capacity of the battery into at least two, if a firstinput operation is entered when the first image is displayed to providea battery blocks set up.

The calculation module calculates a capacity ratio based on capacity ofeach of the battery blocks and the full capacity, and a remainingbattery block capacity of each of the battery blocks based on thecapacity ratio. The function allocation module allocates at least onefunction to at least one of the battery blocks. The processor causes thedisplay module to display a plurality of second images indicating thecapacity ratio and the remaining battery block capacity of correspondingbattery block, and display the function allocated to one of the batteryblocks for one of the second images, when the battery blocks are set.

In an embodiment, a method for operating mobile electronic devicereceives an input operation by a user, stores functions, and measures aremaining battery capacity of a battery. The method further displays afirst image indicating the remaining battery capacity and full capacityof the battery. The method further sets a plurality of battery blocks bydividing the full capacity of the battery into at least two, if a firstinput operation is entered when the first image is displayed, to providea battery blocks set up. The method further calculates a capacity ratiobased on capacity of each of the battery blocks and the full capacity,and calculating a remaining battery block capacity of each of thebattery blocks based on the capacity ratio. The method further allocatesat least one function to at least one of the battery blocks, anddisplays a plurality of second images indicating the capacity ratio andthe remaining battery block capacity. The method further displays thefunction allocated to one of the battery blocks for one of the secondimages, when the battery blocks are set.

In a further embodiment, a non-transitory computer readable storagemedium comprises computer-executable instructions for operating a mobileelectronic device. The method executed by the computer-executableinstructions receives an input operation by a user, stores functions,and measures a remaining battery capacity of a battery. The methodexecuted by the computer-executable instructions further displays afirst image indicating the remaining battery capacity and full capacityof the battery. The method executed by the computer-executableinstructions further sets battery blocks by dividing the full capacityof the battery into at least two, if a first input operation is enteredwhen the first image is displayed, to provide a battery blocks set up.

The method executed by the computer-executable instructions furthercalculates a capacity ratio based on capacity of each of the batteryblocks and the full capacity, and calculates a remaining battery blockcapacity of each of the battery blocks based on the capacity ratio. Themethod executed by the computer-executable instructions furtherallocates at least one function to at least one of the battery blocks,and displaying a plurality of second images indicating the capacityratio and the remaining battery block capacity in place of the batteryimage. The method executed by the computer-executable instructionsfurther displays the function allocated to one of the battery blocks forone of the second images, when the battery blocks are set.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present disclosure are hereinafter described inconjunction with the following figures, wherein like numerals denotelike elements. The figures are provided for illustration and depictexemplary embodiments of the present disclosure. The figures areprovided to facilitate understanding of the present disclosure withoutlimiting the breadth, scope, scale, or applicability of the presentdisclosure.

FIG. 1 is an illustration of a schematic block diagram of a mobile phoneaccording to an embodiment of the disclosure.

FIG. 2 is an illustration of an exemplary standby screen displayed on adisplay shown in FIG. 1.

FIGS. 3A to 3C are illustrations of an exemplary settings screendisplayed on the display shown in FIG. 1.

FIG. 4 is an illustration of an exemplary configuration of functionalgroup data stored in a Random Access Memory (RAM) shown in FIG. 1.

FIGS. 5A to 5D are illustrations of an exemplary detail screen displayedon the display shown in FIG. 1.

FIGS. 6A and 6B are illustrations of an exemplary configuration ofbattery setting data stored in a Random Access Memory (RAM) shown inFIG. 1.

FIGS. 7A and 7B are illustrations of an exemplary detail screendisplayed on the display shown in FIG. 1.

FIGS. 8A and 8B are illustrations of an exemplary detail screendisplayed on the display shown in FIG. 1.

FIG. 9 is an illustration of an exemplary configuration of batterysetting data stored in the Random Access Memory shown in FIG. 1.

FIG. 10 is an illustration of an exemplary standby screen displayed onthe display shown in FIG. 1.

FIGS. 11A and 11B are illustrations of an exemplary detail screendisplayed on the display shown in FIG. 1.

FIG. 12 is an illustration of an exemplary memory map of the RandomAccess Memory shown in FIG. 1.

FIG. 13 is an illustration of an exemplary detail of a data storage areain a memory map shown in FIG. 12.

FIG. 14 is an illustration of a flow diagram showing an exemplaryprocess for calculating a slide distance according to an embodiment ofthe disclosure.

FIG. 15 is an illustration of a flow diagram showing an exemplaryprocess for determining a slide direction according to an embodiment ofthe disclosure.

FIG. 16 is an illustration of a flow diagram showing an exemplaryprocess for determining set up function groups according to anembodiment of the disclosure.

FIG. 17 is an illustration of a flow diagram showing an exemplaryprocess for controlling a power supply according to an embodiment of thedisclosure.

FIG. 18 is an illustration of a flow diagram showing an exemplarysetting process according to an embodiment of the disclosure.

FIGS. 19-22 is an illustration of a flow diagram showing an exemplaryediting process according to an embodiment of the disclosure.

FIG. 23 is an illustration of an exemplary standby screen displayed onthe display shown in FIG. 1 according to an embodiment of thedisclosure.

DETAILED DESCRIPTION

The following description is presented to enable a person of ordinaryskill in the art to make and use the embodiments of the disclosure. Thefollowing detailed description is exemplary in nature and is notintended to limit the disclosure or the application and uses of theembodiments of the disclosure. Descriptions of specific devices,techniques, and applications are provided only as examples.Modifications to the examples described herein will be readily apparentto those of ordinary skill in the art, and the general principlesdefined herein may be applied to other examples and applications withoutdeparting from the spirit and scope of the disclosure. The presentdisclosure should be accorded scope consistent with the claims, and notlimited to the examples described and shown herein.

Embodiments of the disclosure are described herein in the context of onepractical non-limiting application, namely, a mobile electronic devicesuch as a mobile phone. Embodiments of the disclosure, however, are notlimited to such mobile phone, and the techniques described herein may beutilized in other applications. For example, embodiments may beapplicable to digital books, digital cameras, electronic game machines,digital music players, personal digital assistance (PDA), personal handyphone system (PHS), lap top computers, TV's, iPod™, iPad™, displaymonitors, or other electronic device that uses a display screen or atouch panel for displaying information and comprises a battery.

As would be apparent to one of ordinary skill in the art after readingthis description, these are merely examples and the embodiments of thedisclosure are not limited to operating in accordance with theseexamples. Other embodiments may be utilized and structural changes maybe made without departing from the scope of the exemplary embodiments ofthe present disclosure.

FIG. 1 is an illustration of a schematic block diagram of a mobile phone10 according to an embodiment of the disclosure. As shown in FIG. 1, themobile phone 10 according to the present embodiment may comprise aprocessor 24 comprising a computer or a CPU. The processor 24 is coupledto a wireless communication circuit 14, an A/D converter 16, a D/Aconverter 20, a key input device 26, a display driver 28, a memorymodule 50, a touch panel control circuit 36, an acceleration sensor 40,and a power supply circuit 42.

The wireless communication circuit 14 is coupled to an antenna 12. TheA/D converter 16 is coupled to a microphone 18. The D/A converter 20 iscoupled to a speaker 22. The display driver 28 is coupled to a display30. The touch panel control circuit 36 is also coupled to a touch panel38. The power supply circuit 42 is coupled to a secondary cell 44 and anexternal power supply connector 46.

The processor 24 is capable of controlling functions of the mobile phone10. The processor 24 may be implemented or realized with a generalpurpose processor, a content addressable memory, a digital signalprocessor, an application specific integrated circuit, a fieldprogrammable gate array, any suitable programmable logic device,discrete gate or transistor logic, discrete hardware components, or anycombination thereof, designed to perform the functions described herein.In this manner, a processor may be realized as a microprocessor, acontroller, a microcontroller, a state machine, or the like. A processormay also be implemented as a combination of computing devices, e.g., acombination of a digital signal processor and a microprocessor, aplurality of microprocessors, one or more microprocessors in conjunctionwith a digital signal processor core, or any other such configuration.

The memory module 50 may be any suitable data storage area with suitableamount of memory that is formatted to support the operation of themobile phone 10. Memory module 50 is configured to store, maintain, andprovide data as needed to support the functionality of the mobile phone10 in the manner described below. In practical embodiments, the memorymodule 50 may comprise, for example but without limitation, anon-volatile storage device (non-volatile semiconductor memory, harddisk device, optical disk device, and the like), a random access storagedevice (for example, SRAM, DRAM), or any other form of storage mediumknown in the art.

For example the memory module 50, may comprise a RAM 34 and a flashmemory 32. The RAM 34 is used as a work area (including a drawing area)or as a buffer area for the processor 24. A flash memory 32 storescontent data of the mobile phone 10, such as but without limitation,characters, letters, images, audios, sounds, movies, or other contentdata. The memory module 50 may be coupled to the processor 24 andconfigured to store, for example but without limitation, a batterycapacity, a remaining battery capacity, or other data.

The A/D converter 16 converts analog audio signals of audios or soundsinput through the microphone 18 to digital audio signals. The D/Aconverter 20 converts (decodes) the digital audio signals to analogaudio signals and provides the converted analog signals to the speaker22 through an amplifier not shown in Figures. The audios or soundscorresponding to the analog audio signals are output from the speaker22. The processor 24 is capable of adjusting volume of the audio outputfrom the speaker 22 by controlling an amplification factor of anamplifier.

The key input device 26 comprises a home key for returning to a standbystate, a call key, and an end-call key. The data of key (the key data)operated by a user is output to the processor 24. Operating each keycomprises in the key input device 26 makes a click sound. By hearing theclick sound, a user is able to recognize the key is operated.

The display driver 28 controls a display on the display 30 coupled tothe display driver 28 according to the instruction from the processor24. The display driver 28 also comprises a video memory (not shown) fortemporarily storing video data to be displayed.

The display 30 is configured to display various kinds of information viaan image/video signal supplied from the processor 24. The display 30 mayaccept a user input operation to input and transmit data, and inputoperation commands for functions provided in the mobile phone 10. Thedisplay 30 accepts the operation command, and outputs operation commandinformation to the processor 24 in response to the accepted operationcommand. The display 30 may be formed by, for example but withoutlimitation, an organic electro-luminescence (OEL) panel, liquid crystalpanel (LCD), and the like.

The touch panel 38 employs a system of capacitance, which detectschanges of capacitance between electrodes caused by approximation of anobject, such as a finger, to the surface; for example, the system maydetect that one or more fingers touch the touch panel 38. The touchpanel 38 is arranged on top of the display 30 and used as a pointingdevice for a user to specify an arbitrary location within the screen ofthe display 30. The touch panel control circuit 36 (detection module),detects various types of touch operations such as but withoutlimitation, pressing, stroking, and touching, within the touch effectivearea of the touch panel 38 and outputs the coordinate data of thedetected location of the touch operation to the processor 24. That is, auser may input a direction of operation or graphic to the mobile phone10 by pressing, stroking, and touching the surface of the touch panel 38with a finger or the like.

An operation of a user touching on a top surface of the touch panel 38with a finger is referred to as a “touch.” By contrast, an operation ofreleasing a finger from the touch panel 38 is referred to as a“release.” An operation of a user touching and then releasing from thetop surface of the touch panel 38 is referred to as a “touch andrelease.”

An operation of stroking the surface of the touch panel 38 is referredto as a “slide” and an operation of touching, sliding and then releasingis referred to as a “touch-slide.” Furthermore, an operation of touchingand releasing continuously twice is referred to as a “double-tap,” andan operation of touching more than two locations almost simultaneouslyis referred to as a “multi-touch.” The “touch operation” includes theabove “touch” “release,” “touch and release,” “slide,” “touch-slide,”“double-tap,” “multi-touch,” and the like.

Furthermore, a coordinate identified by a touch is referred to as a“touched point” (a starting location of a touch,” and a coordinateidentified by a release is referred to as a “released point” (afinishing location of a touch).

In addition, a touch operation may be performed not only by a finger butalso by other objects, such as but without limitation, a touch pen, orother objects comprising a conductive material on a nib. The detectingsystem for the touch panel 38 may comprise, for example but withoutlimitation, a capacitance system, a resistive system, an ultrasonicsystem, an infrared system, an electromagnetic induction system, orother system.

The acceleration sensor 40 comprises a semiconductor triaxialacceleration sensor, and it outputs triaxial acceleration data (X, Y,and Z) with respect to the mobile phone 10 to the processor 24. Theprocessor 24 applies an inverse trigonometric function to a valueindicated by the triaxial acceleration data and calculates the angle ofthe inclination of the mobile phone 10. For this reason, theacceleration sensor 40 is used as an inclination sensor detecting theinclination of the position of the mobile phone 10.

The touch panel control circuit 36, the touch panel 38, and theacceleration sensor 40 receive an instinctive input operation withrespect to the mobile phone 10 from a user and may be called an inputmodule. Thus, the mobile phone 10 may detect touch operations and theother operations, such as a tilt operation tilting the mobile phone 10or a shake operation shaking the mobile phone 10, as input operations.

The power supply circuit 42 comprises an integrated circuit (IC) forpower management, which comprises functions such as a measuring moduleand a charging module. The power supply circuit 42 is coupled to thesecondary cell 44 of power supply such as a lithium-ion battery, and theexternal power supply connector 46. The power supply circuit 42 alsomeasures and outputs the remaining battery capacity of the secondarycell 44 to the processor 24. The power supply circuit 42 provides powerbased on the voltage of the secondary cell 44 to the entire system. Whenthe power supply circuit 42 provides power to the entire mobile phone 10(system 10), the condition is referred to as a “power-on state.”

By contrast, when the power supply circuit 42 does not provide power tothe entire system 10, the condition is referred to as a “power-offstate.” However, power is always provided to the processor 24 even in apower-off state, because it is necessary to receive key data from thekey input device 26. The power supply circuit 42 is switched to apower-on state when the key input device 26 performs a power-onoperation in a power-off state and is switched to a power-off state whenthe key input device 26 performs a power-off operation in a power-onstate. The power supply circuit 42 starts up when the external powersupply connector 46 is coupled to an external power source and whenpower is provided (charged) to the secondary cell 44 in a power-offstate. The power supply circuit 42 shuts down when detecting thesecondary cell 44 is fully charged.

In the present embodiment, a lithium-ion battery is used as thesecondary cell 44, but without limitation, a lead-storage battery,nickel-hydride battery, sodium-ion battery, metal-air battery, zincbromide battery, or other batteries may be used. Furthermore, a primarycell may also be used in place of the secondary cell 44.

The external power supply connector 46 is coupled to an external powersource converted from alternating-current power source, such as an ACadapter, or to an external power source converted from direct-currentpower source, such as a DC adapter. The external power supply connector46 may be coupled to an external power source through a USB cable or thelike.

In this document, “charging” means that the secondary cell 44 storeselectric energy as a result of electric power provided from an externalpower source to the secondary cell 44. Then the processor 24 detects thefull charge condition based on a value of current measured by the powersupply circuit 42.

The wireless communication circuit 14 is operable to transmit andreceive a plurality of communication signals comprising data signals viaa base station. The wireless communication circuit 14 communicates withthe wireless network via a wireless data communication link (not shown).The wireless communication circuit 14 cooperates with a base stationtransceiver (not shown) with a suitably configured RF antennaarrangement 12 (antenna 12) that can support a particular wirelesscommunication protocol and modulation scheme to transmit and receive thedata signals form and to the processor 24.

The wireless communication protocol and modulation scheme may comprise,for example but without limitation, Code Division Multiple access(CDMA), Third Generation Partnership Project Long Term Evolution (3GPPLTE)TM, Third Generation Partnership Project 2 Ultra Mobile Broadband (3Gpp2 UMB) TM, Time Division-Synchronous Code Division Multiple Access(TD-SCDMA) TM, Wireless Interoperability for Microwave Access (WiMAX),or other wireless communication protocol and modulation scheme.

For example, in operation, when a user gives an instruction to place acall using the key input device 26, the wireless communication circuit14 performs an outgoing call process and outputs outgoing-call signalsthrough the antenna 12 according to the instruction of the processor 24.The outgoing-call signals are transmitted to a telephone set at a callreceiver side (callee) through base stations and communication networks(not shown). When the telephone set at the call receiver side performsthe incoming-call process, the communication becomes available, and theprocessor 24 performs a call process (telephonic communication process).

A call process is described below. The antenna 12 receives modulatedaudio signals transmitted from a telephone set at the other side. Thewireless communication circuit 14 performs demodulation and decodingprocesses on the received modulated audio signals. The wirelesscommunication circuit 14 outputs the modulated audio signals on whichthe demodulation and decoding processes are performed as received audiosignals. The received audio signals are converted to analog audiosignals by the D/A converter 20 and output from the speaker 22.

Transmitted audio signals taken in through the microphone 18 areconverted to digital audio signals by the A/D converter 16 and output tothe processor 24. Based on the instruction of the processor 24, thewireless communication circuit 14 performs encoding and modulationprocesses on the digital audio signals. The digital audio signals onwhich the encoding and modulation processes are performed are outputthrough the antenna 12. Thus, the modulation audio signals aretransmitted to the telephone set at the other side through base stationsand communication networks.

When the antenna 12 receives outgoing-call signals transmitted from atelephone set at the other side, the wireless communication circuit 14notifies to the processor 24 that a call (an incoming call) is received.The processor 24 controls the display driver 28 and causes the display30 to display the originator's information (such as a telephone number)included in the outgoing-call signals. The processor 24 also causes tooutput a ring tone (alternatively called a ringer melody or incomingcall sound) from a speaker (not shown) and to spin a motor of a vibrator(not shown).

When a user performs a reply operation to an incoming call using a callkey, the wireless communication circuit 14 performs a receiving-a-callprocess based on the instruction of the processor 24. After thereceiving-a-call process is performed, communication becomes available.The processor 24 performs the above-mentioned call process oncecommunication becomes available.

When a user performs an end-call operation by operating an end-call keyafter communication becomes available, the processor 24 controls thewireless communication circuit 14 and transmits end-call signals to theother party. Then the processor 24 terminates the call process aftertransmitting the end-call signals. The processor 24 also terminates thecall process when receiving end-call signals from the other party. Theprocessor 24 also terminates the call process when receiving end-callsignals not from the other party, but from a mobile communicationnetwork. In addition, an outgoing-call process and/or a call process arereferred to as a phone function.

The mobile phone 10 is capable of performing a browsing function that auser performs to browse data stored in a server and other functions.Furthermore, a user may add arbitrary functions (applications), such asa music player for listening to music, by establishing communicationswith a server through networks.

FIG. 2 is an illustration showing an exemplary display of the display 30in the standby condition. The display of the display 30 comprises anantenna icon AIa indicating the reception condition by the antenna 12, abattery icon BIa indicating a remaining battery capacity to the fullcapacity of the secondary cell 44, a condition display area 60 showingtime and date, and a function display area 62, in which a standby screenis displayed. The antenna icon AIa and the battery icon BIa displayed inthe condition display area 60 respectively have other kinds. When thereis no need to distinguish a kind of an antenna icon, it is simplyreferred to as an “antenna icon AI.” When there is no need todistinguish a kind of a battery icon, it is simply called a “batteryicon BI.”

As shown in FIG. 3A, when the battery icon BIa is touched longer than apredefined time (a touch of pressing long), the setting screen isdisplayed on the display 30. The setting screen comprises an additionalfunction list. The additional function list comprises a column entitled“functions” where functions added by a user are displayed and a columnentitled “function groups” where function groups for classifying theadded functions are displayed. In the column of “functions,” thefollowings are displayed as examples of the functions added by a user: a“puzzle” indicating a function of a puzzle game, a “music player”indicating a function of playing and managing music data, an “auction”indicating a function of assisting use of an auction site, an“electronic guitar” indicating a function of electronic instruments, a“recorder” indication a function of recording surrounding audios/sounds,and a “photo” indicating a function of managing image data by uploadingto a server.

Furthermore, in the column of the “function groups,” function groups ofa “call,” “browser,” and “music” are displayed as examples. The “call”is a function group for classifying functions of exchangingaudios/sounds, such as a phone function. The “browser” is a functiongroup for classifying communication functions between servers throughnetworks. The “music” is a function group for classifying functions ofplaying and recording of audios/sounds.

In the additional function list shown in FIG. 3A, the function of the“puzzle” is associated with the function group, “game”; the function ofthe “music player” is associated with the function group, the “music”;the function of the “auction” is associated with the function group, the“browser”; and the functions of a “electronic guitar” and a “recorder”are associated with the function group, the “music.” In FIG. 3A, nofunction group is set for the function of a “photo.” When a user touchesa field where no function group is set, the user may set the functiongroup for the corresponding function (the function of the “photo” inFIG. 3A).

As shown in FIG. 3B, when a touch operation is performed to the field inthe column of the function group, in the row of the “photo,” a pull-downmenu P for selecting a function group is displayed. If the functiongroup, “browser,” is touched among the function groups shown in thepull-down menu P, the function, “photo,” is associated with the functiongroup, “browser,” as shown in FIG. 3C.

When a touch operation is performed on the “new group,” a new entryprocess for recording a new function group is performed. When the newentry process is performed, a graphic user Interface (GUI) for recordinga name of a function group is displayed. If a touch operation isperformed on the field where a function group has already been set, thefunction group may be reset.

When a function group is set, function group data stored in the RAM 34is updated. As shown in FIG. 4, the function group data comprises acolumn recording names of function groups, a column recording consumedcurrent, and a column recording classified functions. For example, theconsumed current of the function group, the “call,” is “XXX,” and thecall function group comprises a “phone function” as a classifiedfunction. The consumed current of the function group, the “browser,” is“YYY,” and the browser function group comprises “browsing,” “auction,”and “photo” functions as a classified function.

The function group, the “music,” comprises a “music player,” an“electronic guitar,” and a “recorder” as a classified function; however,these classified functions are newly added by a user, and therefore, noconsumed current is set up at this point. The consumed current of thefunction group, the “music,” is set up when the function of the “musicplayer,” “electronic guitar,” or “recorder” is performed. For example,when the music player is executed, a value of the consumed current ismeasured, and the measured result is set up as the consumed current ofthe “music.”

Thus, a user may freely configure a function group even with a functionadded arbitrarily. The value of the consumed current for a newly addedfunction group is measured when a classified function is executed, andthe measured result is automatically set up. For this reason, the mobilephone 10 may find the estimated time described below, even for an addedfunction.

In addition, a user may arbitrarily set up consumed current. Thefollowing explanation is based on the premise that the consumed currentof the function group, the “music,” is set up as “XXX.”

FIG. 5A shows that the detail screen is displayed on the display 30 whena double-tap to the battery icon BIa is performed. The antenna icon AIais replaced with an antenna icon AIb in the condition display area 60 ofthe detail screen. Because the battery icon BIa is deleted, thecondition display area 60 in FIG. 4 is smaller than the conditiondisplay area 60 in FIG. 3. A first battery image BGa and a battery groupare also displayed in the function display area 62. The first batteryimage BGa indicates the remaining battery capacity to the full capacityof the secondary cell 44.

A graphic resembling a battery indicates the full capacity in the firstbattery image BGa. The area shaded with diagonal lines indicates theremaining battery capacity. In FIG. 5A, when the full capacity is set to“100,” the remaining battery capacity is indicated as “80.” Furthermore,a touch-operation effective area ETa is provided to the first batteryimage BGa, as described hereinafter. Hereinafter, when a battery imageis not distinguished, it is simply described as the “battery image BG.”Also battery image and battery block image may be used interchangeablyherein.

A battery group shown below the battery image BG comprises at least oneor more function groups. The battery group is associated with thebattery image BG. Each function group in the battery group is associatedwith an estimated time. The estimated time is the time when a functionin the function group may be used. The estimated time is calculatedbased on the remaining battery capacity and the consumed currentrecorded in the function group data. For example, when the remainingbattery capacity is “80,” the estimated time is “10:00” for the call,“5:00” for the browser, and “50:00” for the music. A user may use theestimated time as a reference and create a utilization plan of themobile phone 10.

Even if a user creates a utilization plan, it may be difficult to usethe mobile phone 10 in such a way as to leave certain remaining batterycapacity. In an embodiment, by a touch operation, a plurality of batteryblocks are set up by dividing the full capacity of the secondary cell44, and a battery group including an arbitrary function group may beallocated to at least one battery block. Thus, a user may allocate abattery block to a function (function group) mainly used and may use thefunction without worrying about the remaining battery capacity.

As shown in FIG. 5B, when a touch operation is performed in theeffective area ETa, an auxiliary line GL, both ends of which are arrows,and a parting line DL indicated as a dashed line are displayed tocorrespond with the first battery image BGa. A pointer Po is displayedat the intersection point of the auxiliary line GL and the paring lineDL and the location touched by a finger.

The pointer Po may be moved on the auxiliary line GL right and left. Theparting line DL is a line for dividing the first battery image BGa toright and left. The parting line DL preliminarily indicates the ratio ofthe battery block to be divided. In the following description, the leftside of the parting line DL on the first battery image BGa is referredto as a first virtual battery block, and the right side as a secondvirtual battery block.

The displayed location of the pointer Po and the parting line DL changesas the pointer Po moves (as the touched location moves). A user maychange the ratio between the first virtual battery block and the secondvirtual battery block by sliding a finger along the auxiliary line GL.Furthermore, when a battery block is set up, the capacity ratio and theremaining battery block capacity are displayed to correspond with thefirst virtual battery block and the second virtual battery block.

The capacity ratio and the remaining battery block capacity aredisplayed under the battery image BG. The first battery group isdisplayed to correspond with the first virtual battery block, and thesecond battery group is displayed to correspond with the second virtualbattery block. At this time, the first battery group takes over thefunction groups included in the original battery group while the secondbattery group does not include any function group.

In FIG. 5B, the parting line DL is displayed to intersect with alocation of “7” in the first battery image BGa, and that enables to seethat the full capacity of the secondary battery/cell 44 is divided intothe first virtual battery block and the second virtual battery block inthe ratio of “7:3.” Furthermore, the “Remaining capacity: 56/70”displayed at the lower left side of the first battery image BGacorresponds to the first virtual battery block, and that enables to seethat the remaining battery block capacity of the first virtual batteryblock is “56.” On the other hand, “Remaining capacity: 24/30” displayedat the lower right side of the first battery image BGa corresponds tothe second virtual battery block, and that enables to see that theremaining battery block capacity of the second virtual battery block is“24.”

Thus, the remaining battery capacity is divided in the same ratio, inwhich the full capacity is divided. That is, if the original remainingbattery capacity is 80 (80%), and if the dividing ratio is “7:3,” theremaining battery block capacity of the first battery block is 56 (70%),and the remaining battery block capacity of the second battery block is24 (30%).

The display of the first battery group is recalculated in conjunctionwith the remaining battery block capacity of the first virtual batteryblock. For this reason, when the remaining battery block capacity is“56,” the estimated time for the call is changed from “10:00” to “7:00,”the estimated time for the browser from “5:00” to “3:30,” and theestimated time for the music from “50:00” to “35:00.” Therefore, a usermay perform a touch operation of moving a pointer to right and left byreference to the estimated time displayed for a battery group.

As shown in FIG. 5C, when a slide is performed in such a way as to tracethe parting line DL, the ratio corresponding to the first virtualbattery block and the second virtual battery block is determined, andthe display is changed to one shown in FIG. 5D. That is, in place of thefirst battery image BGa, a second battery image BGb provided with aneffective area ETb and a second battery image BGc provided with aneffective area ETc are displayed.

As a result, a user may intuitively divide the full capacity of thesecondary cell 44 by a touch operation. Setting up battery blocksaccidentally is also prevented by combining touch operations of a touchand a slide. Furthermore, a user may use the second battery block thatis not allocated to a function group as a backup remaining batterycapacity. That is, in the subject embodiment, all battery blocks do notneed to be allocated to a function group.

When a consumed current is not set for a function group, “-,” indicatingthe estimated time may not be calculated, may be displayed in the columnof the battery group. A value of the estimated time displayed as “-” isindicated after the consumed current value is set.

As shown in FIGS. 6A and 6B, the divided full capacity of the secondarycell 44 is stored in the RAM 34 as battery setting data. If a batterycapacity block is not set up, the battery setting data is indicated asshown in FIG. 6A. When the battery capacity block is not set up, thebattery setting data comprises a column for “Remaining batterycapacity/Battery capacity” where “80/100” is recorded and a column for“Battery groups” where function groups, such as the “call, browser, andmusic” are recorded.

Next, when a battery block is set up, a column for “Battery blocks” isnewly added to the battery setting data, and the column for “Remainingbattery capacity/battery capacity” is replaced with one for “Remainingbattery capacity block/capacity ratio.” In a column entitled “Remainingbattery block/capacity ratio”, a row entitled “First battery block”,“56/70” is recorded. In a column entitled the battery groups, the rowentitled the first battery block, the function groups of “call, browser,and music” are recorded. In the column entitled “Remaining batteryblock/capacity ratio,” a row entitled the “second battery block,”“24/30” is recorded. However, as shown in FIG. 5D, if the second batterygroup does not include a function group, nothing is recorded in thefield of “Battery groups.”

When a function is executed in the mobile phone 10, the remainingbattery capacity of the secondary cell 44 is managed based on thebattery setting data. For example, when a phone function included in thefunction group, “Call,” is executed, the remaining battery capacity ismanaged as “56.”

The battery setting data is updated at a constant frequency. In thesubject embodiment, electric power consumed in a standby condition isreflected in a remaining battery block capacity of the first batteryblock that is allocated to the function group of “Call.” However, thepower consumed in the standby condition may be reflected in theremaining battery block capacity of the second battery block that is notallocated to the function group, “Call,” or in the remaining capacity ofthe both first and second battery blocks. The power consumed in astandby condition may be reflected in the battery block that has morecapacity ratio. The power consumed in the standby condition may be alsoreflected in a battery block with more remaining battery block capacity.

As shown in FIGS. 7A and 7B, a user may move a function group to anarbitrary battery block by a touch operation to the function group. Forexample, when the function group, the “music,” is touched, the processor24 highlights the display of the text indicating the function group ofthe music, that is, the text of “Music 35:00.” When the processor 24detects that the touched location enters the display area of the secondgroup by a slide, it calculates the estimated time for the functiongroup of the “music” based on the remaining battery block capacity ofthe second battery block and the consumed current of the “music”included in the function group data. The processor 24 also displays thefunction group of the “music” and the estimated time in the display areaof the second battery group. When a release is detected in the displayarea of the second battery group, move of the highlighted function groupfrom the first battery group to the second battery group is completed asshown in FIG. 7B.

Thus, a user may allocates an arbitrary function group to an arbitrarybattery group by reference to the estimated time included in the secondbattery images BGb and BGc, and the battery groups. A user may alsoallocate a plurality of functions to a battery block as a whole and,therefore, may not need to perform a complex operation to allocate eachfunction to a battery block.

As shown in FIGS. 8A and 8B, a user may arbitrarily adjust the remainingbattery block capacity of a battery block by performing a touchoperation respectively to the second battery images BGb and BGc. Forexample, when detecting a touch to the second battery image BGc, andwhen detecting that the touched location slides into the display area ofthe first battery image BGb, the processor 24 calculates a quantity tobe transferred per a given period of time (hereinafter, referred to as atransferred quantity) based on the slide distance of the touchedlocation. The processor 24 moves at least a part of the remainingbattery block capacity of the second battery block to the first batteryblock based on the touched period of time and the transferred quantity.That is, the remaining battery block capacity is moved from the secondbattery image BGc (the second battery block) to the second battery imageBGb (the first battery block). A transferred quantity may be calculatedbased on a distance where a touched location slides per a given periodof time.

The processor 24 terminates the transfer of the remaining battery blockcapacity when a release is detected. FIG. 8B shows the result of thetransfer of the remaining battery block capacity. That is, the remainingbattery block capacity of the first battery block is changed from “56”to “68,” and the remaining battery block capacity of the second batteryblock is changed from “24” to “12.” Furthermore, because the remainingbattery block capacity is changed respectively, the estimated time forcall in the first battery group is changed from “7:00” to “8:30,” andthe estimated time for Browser is changed from “4:30” to “4:15.” Theestimated time for the music in the second battery group is also changedfrom “14:30” to “7:15.” However, the total quantity of the remainingbattery block capacity is unchanged, although the remaining batteryblock capacity of each battery block is changed.

Thus, in an embodiment, the remaining battery block capacity of eachbattery block may be adjusted by a touch operation.

A transferred quantity is a quantity of a remaining battery blockcapacity that changes per a given period of time. The processor 24calculates in such a way that longer a slide distance is, more thetransferred quantity becomes. The second battery image BGb and thesecond battery image BGc may also be updated as the remaining batteryblock capacity changes. A user may know the change of the remainingbattery block capacity in real time. The transferred quantity may berecalculated according to the change of the slide distance. Thus, a usermay adjust the transferred quantity of the remaining battery blockcapacity by adjusting the slide distance.

FIG. 9 indicates battery setting data in the condition of FIG. 8B. Thatis, “68/70” is recorded in a row entitled the first battery block, acolumn entitled “Remaining battery block capacity/capacity ratio,” andthe “call, and browser” are recorded in the row entitled the firstbattery block, a column entitled the “Battery groups.” “12/30” isrecorded in a row entitled the “the second battery block,” the columnentitled the “Remaining battery block capacity/capacity ratio,” and the“music” is recorded in the row entitled the second battery block, thecolumn entitled the “Battery groups.”

As shown in FIG. 10, when the processor 24 detects an operation on ahome key in the condition of FIG. 8A, it causes the condition displayarea 60 to display the battery icon BIb indicating that the batteryblock is set up. Thus, a user may recognize that the battery block isset up by the new battery icon BIb.

As shown in FIGS. 11A and 11B, when the processor 24 detects a touchoperation on the both display areas of the second battery image BGb andthe second battery image BGc, it deactivates the battery block setting.For example, when the processor 24 detects a touch on each display areaof the first battery block and the second battery block, that is, whenit detects a multi-touch, the processor 24 executes auxiliary displayfor prompting each touched point to approach. When two touched pointsslide to approach each other, the processor 24 deactivates the batteryblock setting. Specifically, a user touches respective display areas ofthe second battery image BGb and the second battery image BGc with afinger, and the user slide the two touching fingers to get closer.

That is, when the user slides two fingers in such a way as to pinch twobattery blocks as a whole, the battery block setting is deactivated. Asshown in FIG. 11B, the processor 24 displays the first battery imageBGa, in place of the second battery images BGb and BGc, in the functiondisplay area 62 after the deactivation of the battery block setting.Hence, a user may deactivate a battery block setting by an intuitiveoperation.

Having confirmed the remaining battery capacity to the full capacity, auser may set up a battery block and allocate an arbitrary function tothe battery block that is set up. A user may also allocate anarbitrarily added function to a battery block.

FIG. 12 is an illustration showing a memory map of the RAM 34. The RAM34 comprises a program memory area 302 and a data memory area 304. Apart of a program or data is retrieved all at once or retrievedpartially in series as necessary from the flash memory 32 and is storedin the RAM 34.

The program memory area 302 stores programs for operating the mobilephone 10. For example, the programs for operating the mobile phone 10include a slide distance calculation program 310, a slide directiondetermination program 312, a function group setting program 314, abattery control program 316, a setting program 318, and an editingprogram 320. The processor 24 executes these programs and realizesfunctions.

The slide distance calculation program 310 is configured to calculate adistance from a touched point to a current touched location and forstoring the calculated distance in a slide distance buffer 332. Theslide direction determination program 312 is a program for determiningwhether a slide direction is vertical or horizontal based on an angle ofthe slide.

The function group setting program 314 is configured to set a functiongroup to an added function. The battery control program 316 isconfigured to display a detail screen, comprising a battery image BG.The setting program 318 is configured to set a new battery block andedit a battery block. The editing program 320 is configured to adjustremaining battery block capacity of a battery block and to allocate afunction group.

Although a figure is omitted, programs for operating the mobile phone 10include a program for notifying of a condition of audio reception, aprogram for external communication, and other programs.

Referring to FIG. 13, a touch buffer 330, a slide distance buffer 332, aremaining battery capacity buffer 336, a battery setting buffer 338, anestimated time buffer 340, and other buffers are provided to the datamemory area 304, and the data memory area 304 stores the battery settingdata 342, the function group data 344, the GUI data 346, the GUIcoordinate data 348 and other data. In the data memory area 304, a touchflag 350, a vertical slide flag 352, a horizontal slide flag 354, and atouch counter 356 are also provided.

The touch buffer 330 temporarily stores touch coordinate data, such as atouched point, a release point, a current touched location, obtained bya touch operation. The slide distance buffer 332 temporarily stores aslide distance calculated by the slide distance calculation program. Anacceleration buffer 334 temporarily stores an acceleration data outputby the acceleration sensor 40. The remaining battery capacity buffer 336temporarily stores the remaining battery capacity of the secondary cell44, calculated by the power supply circuit 42. The battery settingbuffer 338 temporarily stores the capacity ratio, the remaining batteryblock capacity, and the battery groups when virtual battery blocks areset up. The estimated time buffer 340 temporarily stores a calculatedestimated time.

The battery setting data 342 is the battery setting data shown in FIGS.6A, 6B, and 9. The function group data 344 is the function group datashown in FIG. 4. The GUI data 346 is the data for displaying a menu,such as the antenna icon AI, the battery icon BI, the battery image BG,the battery groups and the like. The GUI coordinate data 348 is the dataindicating the coordinate range of GUI displayed on the display 30 andcomprises the battery icon coordinate data 348 a, the battery imagecoordinate data 348 b, the menu coordinate data 348 c, and other data.

The battery icon coordinate data 348 a is coordinate data indicatingdisplay ranges of the battery icon BIa and BIb displayed in thecondition display area 60. The battery image coordinate data 348 b iscoordinate data indicating the display range and the effective area ETaof the first battery image BGa shown in FIG. 5A and the display rangeand the effective area ETb and ETc of the second battery images BGb andBGc shown in FIG. 5D. The menu coordinate data 348 c indicates thebattery groups shown in FIG. 5 (A), the display range of the firstbattery group and the second battery group shown in FIG. 5D.

The touch flag 350 determines if a touch operation is detected. Forexample, the touch flag 350 comprises one-bit register. When the touchflag 350 is on (satisfied), the value of data is set to “1” in theregister. On the other hand, when the touch flag 350 is off(unsatisfied), the value of data is set to “0” in the register. When atouch operation is not detected, the touch flag 350 is set to be off,and when a touch operation is detected, the touch flag 350 is set to beon.

A vertical slide flag 352 indicates whether it is determined that aslide direction is in a vertical direction. If the slide direction is ina vertical direction, the vertical slide flag 352 is set to be on. Ahorizontal slide flag 354 is a flag indicating whether it is determinedthat a slide direction is in a horizontal direction. If the slidedirection is in a horizontal direction, the horizontal slide flag 354 isset to be on. The touch counter 356 is a counter for measuring time whena touch operation is being performed.

Although a figure is omitted, the data memory area 304 stores data, suchas table data for managing added functions, image data displayed in astandby condition, text data, and other data. A counter and a flagnecessary for operation of the mobile phone 10 are also provided to thedata memory area 304.

The processor 24 may concurrently process a plurality of tasks includingthe slide distance calculation process shown in FIG. 14, the slidedirection determination process shown in FIG. 15, the function groupsetting process shown in FIG. 16, the battery control process shown inFIG. 17, the setting process shown in FIG. 18, the editing process shownin FIGS. 19-22, and other processes, under control of an operatingsystem (OS) based on, for example but without limitation, LINUX™,ANDROID™, Real-Time Executive Operating System (REX), or other operationsystem.

FIGS. 14-22 show various processes 1400-1900 that can be performed bythe processor 24 for operating the mobile phone 10 according variousembodiments of the disclosure. The various tasks performed in connectionwith the processes 1400-1900 may be performed by software, hardware,firmware, a computer-readable medium having computer executableinstructions for performing the process method, or any combinationthereof. The process 1400-1900 may be recorded in a computer-readablemedium such as a semiconductor memory, a magnetic disk, an optical disk,and the like, and can be accessed and executed, for example, by acomputer CPU such as the processor 24 in which the computer-readablemedium is stored.

It should be appreciated that processes 1400-1900 may include any numberof additional or alternative tasks, the tasks shown in FIGS. 14-22 neednot be performed in the illustrated order, and processes 1400-1900 maybe incorporated into a more comprehensive procedure or process havingadditional functionality not described in detail herein. In practicalembodiments, portions of the processes 1400-1900 may be performed bydifferent elements of the mobile phone 10 such as: the wirelesscommunication circuit 14, the A/D converter 16, the D/A converter 20,the key input device 26, the display driver 28, the processor 24, thememory module 50, the touch panel control circuit 36, the accelerationsensor 40, the power supply circuit 42, etc. Process processes 1400-1900may have functions, material, and structures that are similar to theembodiments shown in FIGS. 1-13. Therefore common features, functions,and elements may not be redundantly described here.

FIG. 14 is an illustration of a flow diagram showing an exemplaryprocess 1400 for calculating a slide distance according to an embodimentof the disclosure. When the touch panel 38 is touched, and when thetouch flag 350 is turned on, the processor 24 calculates the slidedistance from a touched point and a current touched location (task S1).For example, the processor 24 may utilize the Pythagorean Theorem andmay calculate the distance between two points. The processor 24 thatexecutes a process of the task S1 functions as the slide distancecalculation module.

Then, the slide distance is stored in the slide distance buffer 332 inthe task S3. The processor 24 determines whether a release is detectedor not in the task S5. For example, the processor 24 determines whetherthe slide flag 352/354 is turned off by a finger being released from thetouch panel 38. If the task S5 is “NO,” that is, if a finger is notreleased, the processor 24 returns to the task S1. The slide distance isrepeatedly calculated until a finger is released. On the other hand, ifthe task S5 is “YES,” that is, if a finger is released, the slidedistance calculation process is terminated.

FIG. 15 is an illustration of a flow diagram showing an exemplaryprocess 1500 for determining a slide direction according to anembodiment of the disclosure. For example, when the touch flag 350 isturned on, the vertical slide flag 352 is turned off in the task S21,and the horizontal slide flag 354 is turned off in the task S23. Inother words, each flag is initialized. Next, the processor 24 determineswhether the slide distance is longer than a predefined distance in thetask S25. That is, if the direction is determined when the slidedistance stored in the slide distance buffer 332 is extremely short, thebattery block may be set by accident, or the capacity ratio may beunintentionally changed. For these reasons, it is determined whether theslide distance is longer than a given distance.

Next, the processor 24 calculates the slide angle from a touched pointand a current touched location in the task S27. For example, taking theright side of the horizontal axis as 0 degree, and the touched point asthe vertex of the angle, the angle of the touched location may be found.Next, the processor 24 determines whether the slide angle is within apredefined angle in the task S29. For instance, it is determined whetherthe slide angle is within a range from 45 degrees to 135 degrees or arange from 225 degrees to 315 degrees. If the task S29 is “YES” (forexample, if the slide angle is 80 degrees,) the processor 24 sets thevertical slide flag 352 to be on (the task S31).

Otherwise, the task S29 is “NO” (for example, if the slide angle is 150degrees,) the processor 24 sets the horizontal slide frag 354 to be on(the task S33). When either flag is set to on, the processor 24determines whether a release is detected in the task S35. In otherwords, the processor 24 determines whether the touch flag 350 is set tobe off or not. If the task S 35 is “NO,” that is, if the touchcontinues, the processor 24 returns to the task S25. In contrast, thetask S 35 is “YES,” that is, if the finger is released from the touchpanel 38, the processor 24 terminates the slide direction determinationprocess.

FIG. 16 is an illustration of a flow diagram showing an exemplaryprocess 1600 for determine set up function groups according to anembodiment of the disclosure. For example, when the power of the mobilephone 10 is turned on, the processor 24 determines whether the batteryicon BI is pressed long (the task S51). Specifically, the processor 24determines whether the touched time calculated by the touch counter 356exceeds a predefined time when the touched point stored in the touchbuffer 330 is within a coordinate range indicated in the battery iconcoordinate data 348 a. If the task S 51 is “NO,” for example, if thetouch operation is not performed on the battery icon BI, the process ofthe task S51 is repeated. If the task S 51 is “YES,” for example, if thebattery icon BIa shown in FIG. 2 is pressed long, the additionalfunction list is created (task S53).

For example, the processor 24 retrieves from the RAM 34 a table formanaging the added functions and further retrieves the correspondingfunction groups when the retrieved functions are in the function groupdata. The processor 24 an adding module creates a function group list,such as one shown in FIG. 3A, based on the retrieved functions and thefunction groups. Next, the processor 24 displays a setting screenincluding a additional function list on the display 30 (task S55). Forinstance, as shown in FIG. 3A, a setting screen comprising an additionalfunction list is displayed on the display 30.

Next, the processor 24 determines whether a function group is touched ornot in the task S57. In other words, the processor 24 determines if oneof any fields in the column entitled “Function Groups” in the additionalfunction list is touched. If the task S57 is “NO,” for example, if atouch operation is not performed on the touch panel 38, the processor 24executes the task S71. If the task S57 is “YES,” for example, if thefield that is corresponding to the “Photo” and is in the column of thefunction group as shown in FIG. 3B is touched, a list of the functiongroups is displayed in the task S59. In short, as shown in FIG. 3B, thepull-down menu P including the list of the function groups is displayedin the proximity of the touched field of the function groups.

Next, the processor 24 determines if a function group is specified inthe task S61. For example, the processor 24 determines whether a touchoperation is performed to specify any of the function groups, the“call,” “browser,” and “music,” in the pull-down menu P shown in FIG.3B. If the task S61 is “YES,” for example, if a touch operation isperformed on the function group, the “browser,” the specified functiongroup is set in the task S63. For instance, the “photo” is added in therow of the “browser” in the function group data. Then, the settingscreen is displayed again in the task S65. In other words, the settingscreen shown in FIG. 3C is displayed on the display 30 to inform a userthat the “browser” is set for the “photo.” When the process of the taskS65 is completed, the processor 24 executes the process of the task S71.The processor 24 that executes the process of the task S63 functions asa function group setting module.

In contrast, the task S61 is “NO,” that is, if a touch operation is notperformed on the function group in the pull-down menu P, the processor24 determines if the “New Group” is specified (the task S67). In short,the processor 24 determines if a touch operation is performed on the AddNew Group displayed at the top of the pull-down menu P. If the task S67is “NO,” that is, if the pull-down menu P remains displayed and if atouch operation is not performed, the processor 24 executes the processof the task S61 again. In contrast, the task S67 is “YES,” that is, if atouch operation is performed on the “New Group”, the processor 24executes the process of creating a new group (task S69). That is, theprocesses to name the function group and to set a consumed current areexecuted.

Next, the processor 24 determines if an exit operation is performed inthe task S71. For instance, the processor 24 may determine if a home keyis operated as an exit operation. If the task S71 is “NO,” that is, ifan exit operation is not detected, the processor 24 executes the processof S57. In contrast, if the task S71 is “YES,” that is, if an exitoperation is detected, the processor 24 terminates the function groupsetting process.

FIG. 17 is an illustration of a flow diagram showing an exemplaryprocess 1700 for controlling a power supply according to an embodimentof the disclosure. For example, when the power of the mobile phone 10 isturned on, the processor 24 determines if a double-tap is performed onthe battery icon BI (the task S81). In other words, the processor 24determines if a double-tap is performed within a coordinate rangeindicated by the battery icon coordinate data 348 a. If the task S81 is“NO,” for example, if a double-tap is not detected, the processor 24repeats the process of the task S81. On the other hand, if the task S81is “YES,” for example, if a double-tap to the battery icon BIa shown inFIG. 2 is detected, the processor 24 retrieves the remaining batterycapacity (the task S83). In short, the processor 24 retrieves theremaining battery capacity of the secondary cell 44 from the remainingbattery capacity buffer 336. Next, the processor 24 retrieves thebattery setting data 342 (the task S85).

Next, the processor 24 determines if a battery block is set in the taskS87. That is, the processor 24 determines if a battery block, such asone shown in FIG. 6B, is recorded in the battery setting data 342. Ifthe task S87 is “NO,” for example, if the battery block, such as oneshown in FIG. 6A, is not recorded in the battery setting data 342, theprocessor 24 calculates the estimated time (the task S89). The processor24 calculates the estimated time for each function group recorded in thebattery setting data 342 based on the retrieved remaining batterycapacity and the consumed current in the function group data 344 andstores the calculated result in a estimated time buffer 340.

Next, the processor 24 causes the display 30 to display the firstbattery image BGa. For example, the processor 24 displays on the display30 the first battery image BGa indicating the remaining battery capacityto the full capacity of the secondary cell 44 based on the remainingbattery capacity retrieved in the task S83. The processor 24, forexample, displays a battery group on the display 30 in the task S93.

For example, the processor 24 retrieves a function group from thebattery setting data 342 and retrieves the estimated time correspondingto the retrieved function group from the estimated time buffer 338.Then, the processor 24 displays the retrieved function groups and theestimated time on the display 30. Thus, the display 30 displays thedetail screen, such as one shown in FIG. 5A. When the process of thetask S93 is completed, the processor 24 executes the process of the taskS103. The processor 24 that executes the process of the task S93 mayfunction as a first display module.

The task S87 is “YES,” that is, if a battery block is recorded in thebattery setting data 342, the processor 24 calculates the remainingbattery block capacity (the task S95). That is, the processor 24re-calculates the remaining battery block capacity of each battery blockbased on the remaining battery capacity retrieved in the task S83 andthe capacity ratio to the full capacity recorded in the battery settingdata 342. The processor 24 calculates the estimated time for eachbattery group in the task S97. For example, in the battery setting data342 shown in FIG. 9, the processor 24 calculates the estimated time forrespective function groups of “Call” and “Browser” in the first batterygroup based on the remaining battery block capacity of the first batteryblock and the function group data 344.

The processor 24 also calculates the estimated time for the functiongroup of the “music” in the second battery group based on the remainingbattery block capacity of the second battery block and the functiongroup data 344. The calculated estimated time is stored in the estimatedtime buffer 340. Next the processor 24 displays the second batteryimages BGb and BGc on the display 30 in the task S99. That is, theprocessor 24 displays the second battery images BGb and BGc on thedisplay 30 based on the re-calculated remaining battery block capacityand each capacity ratio. In the task S101, the processor 24 displayseach battery group on the display 30. For example, the second batteryimage BGb and the second battery image BGc are displayed in associationwith the first battery group and the second battery group. Thus, adetail screen, such as one shown in FIG. 8A, is displayed on the display30.

The processor 24 executes the setting process in the task S103. Thissetting process is discussed in more detail in the context of discussionof FIG. 18 below.

The processor 24 determines if an operation performed by a user is anexit operation or not in the task S105. For example, the processor 24determines if a home key is operated or not. If the task S105 is “NO,”that is, if an exit operation is not performed, the processor 24determines if the setting is modified (the task S107). In other words,the processor 24 determines if the battery setting data 342 is modifiedby a setting process. If the task S107 is “NO,” that is, if the batterysetting data 342 is not modified, the processor 24 executes the processof the task S103.

If the task S107 is “YES,” for example, if a battery block is set andthe battery setting data 342 changes from FIG. 6A to FIG. 6B, theprocessor 24 updates a battery image displayed on the display 30 (thetask S109). For example, the processor 24 displays the second batteryimages BGb and BGc shown in FIG. 5D in the function display area 62 inplace of the first battery image BGa shown in FIG. 5A. Next, theprocessor 24 updates the display of the battery group (the task S111)and executes the process of the task S103. For example, the processor 24displays the first battery group and the second battery group shown inFIG. 5D in the function display area 62 in place of the battery groupshown in FIG. 5.

If the task S105 is “YES,” that is, if an exit operation is detected,the processor 24 also terminates the battery control process.

The processor 24 executing the process of the task S109 functions as asecond display module, and the processor 24 executing the process of thetask S111 functions as a third display module.

FIG. 18 is an illustration of a flow diagram showing an exemplarysetting process according to an embodiment of the disclosure. When thetask S103 is executed during the battery setting process shown in FIG.17, the processor 24 determines if a touch is detected within theeffective area ET (the task S131). That is, the processor 24 determinesif a touched point is within the coordinate range of the effective areaET, which is within the coordinate range of the battery image coordinatedata 348 b. If the task S131 is “YES,” for example, if a touch isdetected within the effective area Eta shown in FIG. 5 A, the processor24 displays the parting line DL on the display 30 (the task S133). Inshort, as shown in FIG. 5B, the parting line DL is displayed based onthe coordinate of the touched location stored in the touch buffer 330.When the parting line DL is displayed, the auxiliary line GL and thepointer Po are also displayed on the display 30.

Next, the processor 24 sets virtual battery blocks based on the partingline DL (the task S135). For example, as shown in FIG. 5B, the processor24 sets the left side of the parting line DL to be a first virtualbattery block and a right side of the parting line DL to be the secondvirtual battery block. Then, the processor 24 calculates the capacityratio and the remaining battery block capacity (the task S137). Forexample, when the parting line DL is at the location of “7” as shown inFIG. 5B, it means that the first virtual battery block account for 70percent of the full capacity and that the second virtual battery blockaccounts for 30 percent of the full capacity.

Then, the remaining battery block capacity is calculated in a samemanner as the capacity ratio. For example, when the parting line DL isat the location of “7,” and when the remaining battery capacity is “80,”the remaining battery block capacity of the first battery block is “56,”and the remaining battery block capacity of the second battery block is“24.” The capacity ratio and the remaining battery block capacities aretemporarily stored in the battery setting buffer 338.

Next, the processor 24 calculates estimated time (the task S139). Forexample, the processor 24 calculates estimated time for the functiongroups (the “call,” “browser,” and “music”) shown in FIG. 5A based onthe remaining battery block capacity of the first virtual battery blockstored in the battery setting buffer 338. The each calculated estimatedtime is stored in the estimated time buffer 340. The processor 24updates the display of the battery groups (the task S141). For example,the processor 24 updates the content displayed in the function displayarea 62 with a content, such as one shown in FIG. 5B, by changing theestimated time for each function group shown in FIG. 5A to the estimatedtime calculated in the task S139.

Next, the processor 24 determines if a touched location slides to rightand left. In other words, the processor 24 determines if the horizontalslide flag 354 is on or not. If the task S143 is “YES,” for example, ifa user changes the touched location to right and left along theauxiliary line GL, the processor 24 executes the process of the taskS133. On the other hand, if the task S143 is “NO,” that is, if a userdoes not move the touched location to right and left, the processor 24determines if a release is detected or not. That is, for example, theprocessor 24 determines if the touch flag 350 is turned off by a fingerbeing released from the touch panel 38. If the task S145 is “YES,” thatis, if a release is detected, the processor 24 terminates the settingprocess and returns to the battery control process.

If the task S145 is “NO,” that is, if a release is not detected, theprocessor 24 determines if a touched location slides downward (the taskS147). The processor 24 determines if the vertical slide flag 352 is onand if the current touched location is below the touched point. If thetask S147 is “NO,” that is, if a touched location does not slidedownward, the processor 24 executes the task S143. By contrast, if thetask S147 is “YES,” for example, if a downward slide is detected asshown in FIG. 5C, the processor 24 updates the battery setting data(task S149). In short, the processor 24 updates the battery setting databased on a capacity ratio and a remaining battery block capacity of thefirst virtual battery block and the second virtual battery block storedin the battery setting buffer 338. Thus, the setting of the batteryblock is established, and the calculation of the capacity ratio and theremaining battery block capacity is finalized and is formally allocatedto a function group. When the process of the task S149 is completed, theprocessor 24 returns to the battery control process.

Otherwise, when a touch is not detected within the effective area ET,the processor 24 terminates the setting process and returns to thebattery control process after executing the editing process (task S151).The editing process is discussed in detail after the next paragraph, andthe explanation is omitted.

The processor 24 that executes the processes of the tasks S135 and S149may functions as a setting module. The processor 24 that executes thetasks S135, S137, and S149 may also function as a calculation module.The processor 24 that executes the task S149 may also function as afunction allocation module. The processor 24 that executes the tasksS139 and S149 may also function as a time calculation module.

FIGS. 19-22 is an illustration of a flow diagram showing an exemplarysetting process according to an embodiment of the disclosure. When theforegoing editing process is executed, the processor 24 determines if atouch is detected within an area where a function group is displayed(the task S171). For example, the processor 24 determines if a functiongroup, such as the “music,” is touched, as shown in FIG. 7A, based onthe touched point stored in the menu coordinate data 348 c and the touchbuffer 330. If the task S171 is “NO,” that is, if a touch is notdetected in an area where a function group is displayed, the processor24 executes the process of the task S191 in FIG. 20.

If the task S171 is “YES,” for example, if a user touches the functiongroup of the “music,” as shown in FIG. 7A, the processor 24 highlightsthe touched function group (task S173). For example, as shown in FIG.7A, the processor 24 adds an underline below the text of the touchedfunction group and changes the typeface to the bold, italic typeface.Next, the processor 24 determines if a release is detected (task S175).That is, the processor 24 determines if the touch flag 350 is turnedoff. If the task S175 is “YES,” that is, if a release is detected, theprocessor 24 deactivates the highlight (task S177). That is, theprocessor 24 returns the text of the function group to its originalstate. When the process of the task S177 is completed, the processor 24terminates the editing process and returns to the setting process.

If the task S175 is “NO,” that is, if a touch by a user continues, theprocessor 24 determines if the touched location is moved to an areawhere another battery group is displayed (task S179). That is, theprocessor 24 determines if the touched location enters into the displayrange of another second battery group, indicated by the menu coordinatedata 348 c. If the task S179 is “NO,” for example, if the touchedlocation does not enter into the display range of another second batterygroup, the processor 24 returns to the process of the task S175. If thetask S179 is “YES,” for example, if the touched location enters into thedisplay range of the second battery group as shown in FIG. 7A, theprocessor 24 calculates the estimated time for a highlighted functiongroup (task S181).

In other words, the processor 24 retrieves the consumed current for thetouched function group from the function group data 344, retrieves theremaining battery block capacity of the battery block corresponding tothe battery group where the touched location is, and calculates theestimated time for the highlighted function group. When the process ofthe task S181 is completed, the battery setting data, in which thefunction group, the “music,” is recorded in the second battery block, isstored in the battery setting buffer 340, and the calculated estimatedtime is stored in the estimated time buffer 340. In other words, thefunction group of the “music” is temporarily allocated to the secondbattery block. In addition, the processor 24 that executes the processof the task S181 may function as a time calculation module.

Next, the processor 24 updates the display of battery groups (the taskS183). For example, as shown in FIGS. 7A and 7(B), the processor 24updates the display of the first battery group and the second batterygroup. Then, the processor 24 determines if a release is detected withinanother battery group. For example, the processor 24 determines if thetouch flag 350 is turned off when the coordinate of the touched locationis within the display range of the second battery group shown in FIG.7A. If the task S185 is “NO,” that is, if a release is not detected, theprocessor 24 returns to the process of the task S179.

If the task S185 is “YES,” for example, if a finger is released withinthe display range of the second battery group, the processor 24 updatesthe battery setting data (the task S187). In short, the battery settingdata 342 is updated based on the content stored in the battery settingbuffer 340. Thus, the allocation of the music function group to thesecond battery block is finalized. When the process of the task S187 iscompleted, the processor 24 terminates the editing process and returnsto the setting process.

Additionally, the processor 24 that executes the processes of the tasksS183 and S187 may function as an allocation module.

Next, in the task S191 shown in FIG. 20, the processor 24 determines ifa user is touching the second battery image BGb and BGc. In other words,the processor 24 determines if a touch is detected either within theeffective area ETb of the second battery image BGb or within theeffective area ETc of the second battery image BGc based on the batteryimage coordinate data 348 a. If the task S191 is “NO,” that is, if theboth second battery images are not touched, or if a touch is detectedwithin the both effective areas of the second battery images, theprocessor 24 proceeds to the task S221 in FIG. 21.

Otherwise, if the task S191 is “YES,” for example, if a touch isperformed within the effective area ETc of the second battery image BGcas shown in FIG. 8(A), the processor 24 determines if a release isdetected (the task S187). If the task S193 is “YES,” that is, if a userreleases his/her finger from the touch panel 38, the processor 24terminates the editing process and returns to the setting process. Ifthe task S193 is “NO,” that is, if a user does not release his/herfinger, the processor 24 determines if a touched location is moved intothe display area of the other second battery image (the task S195). Inother words, the processor 24 determines if a touched location is withinthe effective area ET of another second battery image BG based on thebattery image coordinate data 348 a. If the task S195 is “NO,” forexample, if the touched location remains within the effective area ETc,the processor 24 executes the process of the task S193.

If the task S195 is “YES,” for example, if the touched location is movedinto the touch effective area ETb of the second battery image BGb, theprocessor 24 calculates the transferred quantity per a given period oftime based on the slide distance (the task S197). That is, thetransferred quantity is calculated in such a way that longer the slidedistance is, more the transferred quantity becomes. Next, the processor24 changes each remaining battery block capacity based on thetransferred quantity (the task S199).

For example, when a touched point is within the effective area ETc ofthe second battery image BGc shown in FIG. 8A, when the current touchedlocation is within the effective area ETb of the second battery imageBGb, and when the transferred quantity is “3,” the processor 24subtracts the transferred quantity, “3,” from the remaining batteryblock capacity (for example, “24”) of the second battery image BGc wherea touched point is in the battery setting data 342.

Then the processor 24 adds the transferred quantity, “3,” to theremaining battery block capacity (for example, “56”) of the secondbattery image BGb where the touched location is. The process of the taskS199 is repeated until a release is performed, and therefore, theremaining battery block capacity changes based on how long a touchcontinues.

Next, the processor 24 recalculates the estimated time for each batterygroup (the task S201). For example, the processor 24 recalculates theestimated time for the function groups included in the first batterygroup and the second battery group based on the battery setting data342, in which the remaining battery block capacity is changed. Inaddition, the processor 24 that executes the process of the task S197may function as a first transferred quantity calculation module. Theprocessor 24 that executes the processes of the tasks S197-S201 mayfunction as a changing module.

Next, the processor 24 updates the display of the respective secondbattery images BGb and BGc (task S203). In other words, according to thechanges of the remaining battery block capacity in the battery settingdata 342, the display of the respective second battery images BGb andBGc is updated. The processor 24 updates the estimated time (task S205).That is, the processor 24 changes each estimated time in the firstbattery group and in the second battery group to the estimated timerecalculated in the task S201.

Next, the processor 24 determines if a release is detected or not (taskS207). That is, the processor 24 determines if the touch flag 300 isturned off. If the task S207 is “NO,” that is, if a release is notperformed, the processor 24 determines if the slide distance changes(task S209). In short, the processor 24 determines if the slide distancestored in the slide distance buffer 332 changes or not. If the task S209is “NO,” that is, if the slide distance does not change, the processor24 returns to the task S199 to continue to change the remaining batteryblock capacity. If the task S209 is “YES,” that is, if the slidedistance changes, the processor 24 returns to the task S195 to determineif the touched location goes out of another second battery image or torecalculate the transferred quantity. If the task S207 is “YES,” thatis, if a release is performed, the processor 24 terminates the editingprocess and returns to the setting process.

If the slide direction is the opposite direction, the remaining batteryblock capacity also changes in reverse. In other words, the remainingbattery block capacity of the first battery block reduces, and theremaining battery block capacity of the second battery block increasesinstead.

Next, in the task S221 shown in FIG. 21, it is determined if therespective second battery images BGb and BGc are touched. For example,as shown in FIG. 11A, the processor 24 determines if a multi-touch isdetected by detecting a touch from the respective second battery imagesBGb and BGc. If the task S221 is “NO,” that is, if a multi-touch is notperformed as shown in FIG. 11A, the processor 24 terminates the editingprocess and returns to the setting process. If the task S221 is “YES,”for example, if a multi-touch is detected as shown in FIG. 11A, theprocessor 24 displays a preliminary display (task S223). For example, asshown in FIG. 11A, the arrows for encouraging two fingers to move closerto each other are displayed as the preliminary display.

Next, the processor 24 determines if a release is detected (the taskS225). In other words, it is determined if two fingers are released fromthe touch panel 38. If the task S225 is “YES,” that is, if two fingersare released from the touch panel 38, the processor 24 terminates theediting process and returns to the setting process. If the task S225 is“NO,” that is, if two fingers are not released from the touch panel 38,the processor 24 determines if the distance between two points becomeless than a threshold value (task S227). In other words, it isdetermined if the distance of the touched locations specified by twofingers becomes shorter than the threshold value. If the task S227 is“NO,” for example, if the distance between two points does not change,the processor 24 returns to the process of the task S225.

Otherwise, if the task S227 is “YES,” for example, if a user touches andthen performs an operation, such as pinching the two second batteryimages BGb and BGc, as shown in FIG. 11A, the distance between twopoints become less than the threshold value. Therefore, the processor 24updates the battery setting data (task S229). For example, the batterysetting data 342 shown in FIG. 9 is updated to the battery setting data342 shown in FIG. 6A. In other words, the processor 24 deactivates thebattery block that has been set up. When the process of the task S229 iscompleted, the processor 24 terminates the editing process and returnsto the setting process. The processor 24 that executes the process ofthe task S229 may function as a deactivation module.

In FIG. 8A, the processor 24 may change the remaining battery blockcapacity of each battery block when the acceleration sensor 40 detectsan operation of tilting the position of the mobile phone 10.Specifically, the processor 24 calculates the transferred quantity basedon the output from the acceleration sensor 40 and changes the remainingbattery block capacity based on the transferred quantity and how longthe mobile phone 10 is tilted. Thus, a user may intuitively change theremaining battery block capacity by a simple operation of tilting themobile phone 10.

Additionally, the process of using the acceleration sensor 40 isdiscussed with reference to the flow diagram in FIG. 22. The detailedexplanation is omitted as to the processes that have been explained.

During the editing process, the processor 24 determines if the mobilephone 10 is tilted in the task S241. In other words, the processor 24determines if the mobile phone 10 is tilted in either direction of rightor left according to the acceleration data stored in the accelerationbuffer 334. If the task S241 is “NO,” that is, if the position of themobile phone 10 does not change, the processor 24 proceeds to the taskS221 shown in FIG. 21.

If the task S241 is “YES,” for example, if the mobile phone 10 is tiltedin such a way that the second battery image BGb shown in FIG. 8A is onthe lower side, the processor 24 calculates the transferred quantity pera given period of time based on the tilt (task S243). For example, theprocessor 24 calculates the transferred quantity, such that more tiltedthe mobile phone 10 is, greater the transferred quantity becomes.

Next, the processor 24 changes each remaining battery block capacitybased on the transferred quantity (task S199). In other words, theprocessor 24 changes each remaining battery block capacity in such a waythat the battery block located in the lower side has more remainingbattery block capacity. The processor 24 recalculates the estimated timefor each battery group (task S201), updates the display of each secondbattery image (the task S203), and updates the estimated time (taskS205).

Then, the processor 24 determines if the position of the mobile phone 10is changed in the task S245. In other words, the processor 24 determinesif the acceleration data stored in the acceleration buffer 334 ischanged. If the task S245 is “NO,” that is, if the position is notchanged, the processor 24 returns to the process of the task S199. Onthe other hand, if the task S245 is “YES,” that is, if the position ofthe mobile phone 10 is changed, the processor 24 determines if theposition of mobile phone 10 is restored (task S247). The processor 24determines if the position of the mobile phone 10 returns to the statebefore being tilted based on the acceleration data stored in theacceleration buffer 334.

If the task S247 is “NO,” that is, if the position of the mobile phone10 is not restored, the processor 24 returns to the task S243. On theother hand, if the task S247 is “YES,” that is, if the position of themobile phone 10 is restored, the processor 24 terminates the editingprocess and returns to the setting process. The processor 24 thatexecutes the process of the task S243 may function as a changing moduleand a second transferred quantity calculation module.

In the present embodiment, the processor 24 may deactivate batteryblocks, if an input operation of shaking the mobile phone 10 isperformed when a plurality of battery blocks is displayed. In this case,a multi-touch in a display range of the respective battery blocks is notnecessary, even if more than three battery blocks are set. As a result,the setting is more easily deactivated.

Additionally, in an embodiment, the function icon FIa for executing thebattery control function may be displayed on the standby screen of themobile phone 10, instead of the battery icon BIa, as shown in FIG. 23.In this case, the antenna icon AIb and the battery icon BIc, whosedisplay areas are small, are displayed in the condition display area 60.The function icon FIb for executing a phone function, the function iconFIc for executing a mail function, the function icon FId for executing abrowsing function, and the function icon FIe for executing a musicplayer function are also displayed on the standby screen. A user maycause to display the setting screen by pressing long the function iconFIa and to display the detail screen by a double-tap.

An input operation similar to a touch operation may be detected by usinga pointing device, such as a touch pad, a track ball, a mouse and otherdevices, instead of using the touch panel control circuit 36 and thetouch panel 38.

In the present embodiment, a gyro sensor, instead of the accelerationsensor 40, may detect the tilt of the mobile phone 10.

In the present embodiment, the call function group may also be set fortwo battery groups. In other words, a function group may be respectivelyset for a plurality of battery groups at a same time. Furthermore, afunction may be directly allocated to a battery group.

In addition, a plurality of programs used in the subject embodiment maybe stored in the hard disk drive (HDD) in the server for datadistribution and may be distributed to the mobile phone 10 throughnetworks. The programs may be stored in a storage medium, such as a USBmemory, a memory card, and an optical disk, such as a CD, DVD, andBlue-ray Disc (BD). Then, the storage media may be sold or distributed.When a plurality of programs downloaded through the above-mentionedserver or storage media is installed in a mobile phone with the similarconfiguration of the subject embodiment, the same effect as in thesubject embodiment is enjoyed.

Specific values/numbers discussed in this detailed description, such asbattery capacity, a remaining battery capacity, a capacity ratio, aremaining battery block capacity, and other values/numbers, are all mereexamples and may be arbitrarily changed according to a change to productspecifications.

In this document, the terms “computer program product”,“computer-readable medium”, and the like may be used generally to referto media such as, for example, memory, storage devices, storage unit, orother non-transitory media. These and other forms of computer-readablemedia may be involved in storing one or more instructions for use by theprocessor 24 to cause the processor 24 to perform specified operations.Such instructions, generally referred to as “computer program code” or“program code” (which may be grouped in the form of computer programs orother groupings), when executed, enable a method of using a system suchas the mobile phone 10.

Terms and phrases used in this document, and variations hereof, unlessotherwise expressly stated, should be construed as open ended as opposedto limiting. As examples of the foregoing: the term “including” shouldbe read as meaning “including, without limitation” or the like; the term“example” is used to provide exemplary instances of the item indiscussion, not an exhaustive or limiting list thereof; and adjectivessuch as “conventional,” “traditional,” “normal,” “standard,” “known” andterms of similar meaning should not be construed as limiting the itemdescribed to a given time period or to an item available as of a giventime, but instead should be read to encompass conventional, traditional,normal, or standard technologies that may be available or known now orat any time in the future.

Likewise, a group of items linked with the conjunction “and” should notbe read as requiring that each and every one of those items be presentin the grouping, but rather should be read as “and/or” unless expresslystated otherwise. Similarly, a group of items linked with theconjunction “or” should not be read as requiring mutual exclusivityamong that group, but rather should also be read as “and/or” unlessexpressly stated otherwise.

Furthermore, although items, elements or components of the presentdisclosure may be described or claimed in the singular, the plural iscontemplated to be within the scope thereof unless limitation to thesingular is explicitly stated. The presence of broadening words andphrases such as “one or more,” “at least,” “but not limited to” or otherlike phrases in some instances shall not be read to mean that thenarrower case is intended or required in instances where such broadeningphrases may be absent. The term “about” when referring to a numericalvalue or range is intended to encompass values resulting fromexperimental error that can occur when taking measurements.

1. A mobile electronic device comprising: a battery; an input moduleoperable to receive an input operation by a user; a memory moduleoperable to store a plurality of functions; a measuring module operableto measure a remaining battery capacity of the battery; a display moduleoperable to display a first image indicating the remaining batterycapacity and full capacity of the battery; a setting module operable toset a plurality of battery blocks by dividing the full capacity of thebattery into at least two, if a first input operation is entered whenthe first image is displayed to provide a battery blocks set up; acalculation module operable to calculate: a capacity ratio based oncapacity of each of the battery blocks and the full capacity; and aremaining battery block capacity of each of the battery blocks based onthe capacity ratio; a function allocation module operable to allocate atleast one function to at least one of the battery blocks; a processoroperable to cause the display module to: display a plurality of secondimages indicating the capacity ratio and the remaining battery blockcapacity of corresponding battery block; and display the at least onefunction allocated to the at least one of the battery blocks for the atleast one of the second images, when the battery blocks are set.
 2. Themobile electronic device according to claim 1, wherein: the memorymodule is further operable to classify the at least one function into atleast one of function groups and store the at least one function; thefunction allocation module is further operable to allocate a functiongroup to the at least one of the battery blocks; and the processor isfurther operable to cause the display module to display the functiongroup on the at least one of the second images.
 3. The mobile electronicdevice according to claim 2: further comprising a time calculationmodule operable to calculate an estimated time for a function classifiedin the function group to be used based on the remaining battery blockcapacity and data, when the function group is allocated, wherein: theprocessor is further operable to cause the display module to display thefunction group allocated to the at least one battery block and theestimated time for the at least one of the second images, and the memorymodule is further operable to store data in which the function group isassociated with a value of a consumed current for the function group fora predefined time.
 4. The mobile electronic device according to claim 1:further comprising a touch panel operable to detect a touch operation bythe user; the input module is further operable to detect the touchoperation on the touch panel as the first input operation; and thesetting module is further operable to set the battery blocks that thefull capacity of the battery is divided into, according to the touchoperation on the first image.
 5. The mobile electronic device accordingto claim 1: further comprising a touch panel operable to detect aplurality of types of touch operations by the user, wherein: the inputmodule is further operable to detect the types of touch operations onthe touch panel as the first input operation, and the setting module isfurther operable to set the battery blocks that the full capacity of thebattery is divided into according to the types of the touch operationson the first image.
 6. The mobile electronic device according to claim1, further comprising a changing module operable to change the remainingbattery block capacity when the input module receives a second inputoperation.
 7. The mobile electronic device according to claim 6,wherein: the input module comprises a touch panel operable to detect atouch operation by the user; a slide distance calculation moduleoperable to calculate a slide distance when the touch operation of aslide is detected on the touch panel; the changing module is furtheroperable to calculate a transferred quantity according to the slidedistance, when the touch operation of the slide on the battery blockimages is detected; and the changing module is further operable tochange the remaining battery block capacity calculated for each of thebattery blocks based on the transferred quantity.
 8. The mobileelectronic device according to claim 6, wherein: the input modulefurther comprises a detection module operable to detect a detected tiltof the mobile electronic device, the input operation further comprises atilt operation for tilting the mobile electronic device, the changingmodule further comprises a second transferred quantity calculationmodule operable to calculate a second transferred quantity according tothe detected tilt, when the tilt operation is detected while the secondimages are displayed, and the changing module is further operable tochange the remaining battery block capacity based on the secondtransferred quantity.
 9. The mobile electronic device according to claim4: further comprising a deactivation module operable to deactivate thebattery blocks set up based on a multi-touch to the second images,wherein the processor is further operable to cause the display module todisplay the first image in place of the second images when the batteryblocks set up is deactivated.
 10. The mobile electronic device accordingto claim 1, wherein: the at least one function comprises an arbitrarilyadded function, and the function allocation module is further operableto allocate the arbitrarily added function to the at least one of thebattery blocks.
 11. The mobile electronic device according to claim 10,further comprising a function group setting module operable to set thefunction group for the arbitrarily added function.
 12. The mobileelectronic device according to claim 11 further comprising an addingmodule operable to add a function group, wherein the measuring module isfurther operable to: measure a measured value of a consumed current,when a function in a function group is added by the adding module toobtain an added function group, and when the function in the addedfunction group is executed; and set the measured value in data stored inthe memory module.
 13. The mobile electronic device according to claim4: further comprising a deactivation module operable to deactivate thebattery blocks set up, when a first touch to one of the second imagesand a second touch to another image from among the second images aresimultaneously detected, wherein the display module is further operableto display the first image in place of the second images when thebattery blocks set up is deactivated.
 14. The mobile electronic deviceaccording to claim 6, wherein: the input module comprises a touch paneloperable to detect a touched location where the user touches the touchpanel and further comprises a slide distance calculation module operableto calculate a calculated slide distance when the touched locationmoves, the changing module further comprises a first transferredquantity calculation module operable to calculate a first transferredquantity according to the calculated slide distance when a move of thetouched location is detected from one of the second images to anotherimage from among the second images, and the changing module is furtheroperable to change a first remaining battery capacity of the one of thesecond images and a second remaining battery capacity of the anotherimage based on the first transferred quantity.
 15. A method foroperating mobile electronic device: receiving an input operation by auser; storing a plurality of functions; measuring a remaining batterycapacity of a battery; displaying a first image indicating the remainingbattery capacity and full capacity of the battery; setting a pluralityof battery blocks by dividing the full capacity of the battery into atleast two, if a first input operation is entered when the first image isdisplayed, to provide a battery blocks set up; calculating a capacityratio based on capacity of each of the battery blocks and the fullcapacity; calculating a remaining battery block capacity of each of thebattery blocks based on the capacity ratio; allocating at least onefunction to at least one of the battery blocks; displaying a pluralityof second images indicating the capacity ratio and the remaining batteryblock capacity; and displaying the at least one function allocated tothe at least one of the battery blocks for the at least one of thesecond images, when the battery blocks are set.
 16. The method of claim15, further comprising changing the remaining battery block capacitywhen receiving a second input operation.
 17. The method of claim 15,further comprising: calculating an estimated time for a functionclassified in a function group to be used based on the remaining batteryblock capacity and data, when the function group is allocated;displaying the function group allocated to the at least one batteryblock and the estimated time for the at least one of the second images;and storing data in which the function group is associated with a valueof a consumed current for the function group for a predefined time. 18.A non-transitory computer readable storage medium comprisingcomputer-executable instructions for operating a mobile electronicdevice, the method executed by the computer-executable instructionscomprising: receiving an input operation by a user; storing a pluralityof functions; measuring a remaining battery capacity of a battery;displaying a first image indicating the remaining battery capacity andfull capacity of the battery; setting a plurality of battery blocks bydividing the full capacity of the battery into at least two, if a firstinput operation is entered when the first image is displayed, to providea battery blocks set up; calculating a capacity ratio based on capacityof each of the battery blocks and the full capacity; calculating aremaining battery block capacity of each of the battery blocks based onthe capacity ratio; allocating at least one function to at least one ofthe battery blocks; displaying a plurality of second images indicatingthe capacity ratio and the remaining battery block capacity in place ofthe first image; and displaying the at least one function allocated tothe at least one of the battery blocks for the at least one of thesecond images, when the battery blocks are set.
 19. The non-transitorycomputer readable storage medium of claim 18, further comprisingcomputer-executable instructions for changing the remaining batteryblock capacity when receiving a second input operation.
 20. Thenon-transitory computer readable storage medium of claim 18 furthercomprising computer-executable instructions for: calculating anestimated time for a function classified in a function group to be usedbased on the remaining battery block capacity and data, when thefunction group is allocated; displaying the function group allocated tothe at least one battery block and the estimated time for the at leastone of the second images; and storing data in which the function groupis associated with a value of a consumed current for the function groupfor a predefined time.